Varifold

In mathematics, a varifold is, loosely speaking, a measure-theoretic generalization of the concept of a differentiable manifold, by replacing differentiability requirements with those provided by rectifiable sets, while maintaining the general algebraic structure usually seen in differential geometry. Varifolds generalize the idea of a rectifiable current, and are studied in geometric measure theory.

Varifolds were first introduced by Laurence Chisholm Young in (Young 1951), under the name "generalized surfaces".^[1][2] Frederick J. Almgren Jr. slightly modified the definition in his mimeographed notes (Almgren 1965) and coined the name varifold: he wanted to emphasize that these objects are substitutes for ordinary manifolds in problems of the calculus of variations.^[3] The modern approach to the theory was based on Almgren's notes^[4] and laid down by William K. Allard, in the paper (Allard 1972).

Given an open subset ${\displaystyle \Omega }$ of Euclidean space ${\displaystyle \mathbb {R} ^{n}}$, an m-dimensional varifold on ${\displaystyle \Omega }$ is defined as a Radon measure on the set

${\displaystyle \Omega \times G(n,m)}$

where ${\displaystyle G(n,m)}$ is the Grassmannian of all m-dimensional linear subspaces of an n-dimensional vector space. The Grassmannian is used to allow the construction of analogs to differential forms as duals to vector fields in the approximate tangent space of the set ${\displaystyle \Omega }$.

The particular case of a rectifiable varifold is the data of a m-rectifiable set M (which is measurable with respect to the m-dimensional Hausdorff measure), and a density function defined on M, which is a positive function θ measurable and locally integrable with respect to the m-dimensional Hausdorff measure. It defines a Radon measure V on the Grassmannian bundle of ${\displaystyle \mathbb {R} ^{n}}$

${\displaystyle V(A):=\int _{\Gamma _{M,A}}\!\!\!\!\!\!\!\theta (x)\mathrm {d} {\mathcal {H}}^{m}(x)}$

where

• ${\displaystyle \Gamma _{M,A}=M\cap \{x:(x,\mathrm {Tan} ^{m}(x,M))\in A\}}$
• ${\displaystyle {\mathcal {H}}^{m}(x)}$ is the ${\displaystyle m}$−dimensional Hausdorff measure

Rectifiable varifolds are weaker objects than locally rectifiable currents: they do not have any orientation. Replacing M with more regular sets, one easily see that differentiable submanifolds are particular cases of rectifiable manifolds.

Due to the lack of orientation, there is no boundary operator defined on the space of varifolds.

• Current
• Geometric measure theory
• Grassmannian
• Plateau's problem
• Radon measure

• Almgren, Frederick J. Jr. (1993), "Questions and answers about area-minimizing surfaces and geometric measure theory.", in Greene, Robert E.; Yau, Shing-Tung (eds.), Differential Geometry. Part 1: Partial Differential Equations on Manifolds. Proceedings of a summer research institute, held at the University of California, Los Angeles, CA, USA, July 8–28, 1990, Proceedings of Symposia in Pure Mathematics, vol. 54, Providence, RI: American Mathematical Society, pp. 29–53, ISBN 978-0-8218-1494-9, MR 1216574, Zbl 0812.49032. This paper is also reproduced in (Almgren 1999, pp. 497–521).
• Almgren, Frederick J. Jr. (1999), Selected works of Frederick J. Almgren, Jr., Collected Works, vol. 13, Providence, R.I.: American Mathematical Society, ISBN 978-0-8218-1067-5, MR 1747253, Zbl 0966.01031.
• De Giorgi, Ennio (1968), "Hypersurfaces of minimal measure in pluridimensional euclidean spaces" (PDF), in Petrovsky, Ivan G. (ed.), Trudy Mezhdunarodnogo kongressa matematikov. Proceedings of International Congress of Mathematicians (Moscow−1966), ICM Proceedings, Moscow: Mir Publishers, pp. 395−401, MR 0234329, Zbl 0188.17503.
• Allard, William K. (May 1972), "On the first variation of a varifold", Annals of Mathematics, Second Series, 95 (3): 417–491, doi:10.2307/1970868, JSTOR 1970868, MR 0307015, Zbl 0252.49028.
• Allard, William K. (May 1975), "On the first variation of a varifold: Boundary Behavior", Annals of Mathematics, Second Series, 101 (3): 418–446, doi:10.2307/1970934, JSTOR 1970934, MR 0397520, Zbl 0319.49026.
• Almgren, Frederick J. Jr. (1965), The theory of varifolds: A variational calculus in the large for the ${\displaystyle k}$-dimensional area integrand, Princeton: Princeton University Library, p. 178. A set of mimeographed notes where Frederick J. Almgren Jr. introduces varifolds for the first time: the linked scan is available from Albert - The Digital Repository of the IAS.
• Almgren, Frederick J. Jr. (1966), Plateau's Problem: An Invitation to Varifold Geometry, Mathematics Monographs Series (1st ed.), New York–Amsterdam: W. A. Benjamin, Inc., pp. XII+74, MR 0190856, Zbl 0165.13201. The first widely circulated book describing the concept of a varifold. In chapter 4 is a section titled "A solution to the existence portion of Plateau's problem" but the stationary varifolds used in this section can only solve a greatly simplified version of the problem. For example, the only stationary varifolds containing the unit circle have support the unit disk. In 1968 Almgren used a combination of varifolds, integral currents, flat chains and Reifenberg's methods in an attempt to extend Reifenberg's celebrated 1960 paper to elliptic integrands. However, there are serious errors in his proof. A different approach to the Reifenberg problem for elliptic integrands has been recently provided by Harrison and Pugh (HarrisonPugh 2016) without using varifolds.
• Harrison, Jenny; Pugh, Harrison (2016), General Methods of Elliptic Minimization, p. 22, arXiv:1603.04492, Bibcode:2016arXiv160304492H.
• Almgren, Frederick J. Jr. (2001) [1966], Plateau's Problem: An Invitation to Varifold Geometry, Student Mathematical Library, vol. 13 (2nd ed.), Providence, RI: American Mathematical Society, pp. xvi+78, ISBN 978-0-8218-2747-5, MR 1853442, Zbl 0995.49001. The second edition of the book (Almgren 1966).
• Đào, Trọng Thi; Fomenko, A. T. (1991), Minimal Surfaces, Stratified Multivarifolds, and the Plateau Problem, Translations of Mathematical Monographs, vol. 84, Providence, RI: American Mathematical Society, pp. ix+404, ISBN 978-0-8218-4536-3, MR 1093903, Zbl 0716.53003.
• T. C. O'Neil (2001) [1994], "Geometric measure theory", Encyclopedia of Mathematics, EMS Press
• Simon, Leon (1984), Lectures on Geometric Measure Theory, Proceedings of the Centre for Mathematical Analysis, vol. 3, Canberra: Centre for Mathematics and its Applications (CMA), Australian National University, pp. VII+272 (loose errata), ISBN 978-0-86784-429-0, MR 0756417, Zbl 0546.49019.
• Lin, Fanghua; Yang, Xiaoping (2002), Geometric Measure Theory – An Introduction, Advanced Mathematics (Beijing/Boston), vol. 1, Beijing–New York / Boston, MA: Science Press / International Press, pp. x+237, MR 2030862, Zbl 0546.49019, ISBN 7-03-010271-1 (Science Press), ISBN 1-57146-125-6 (International Press).
• White, Brian (1997), "The Mathematics of F. J. Almgren Jr.", Notices of the American Mathematical Society, 44 (11): 1451–1456, ISSN 0002-9920, MR 1488574, Zbl 0908.01017.
• White, Brian (1998), "The mathematics of F. J. Almgren, Jr.", The Journal of Geometric Analysis, 8 (5): 681–702, CiteSeerX 10.1.1.120.4639, doi:10.1007/BF02922665, ISSN 1050-6926, MR 1731057, S2CID 122083638, Zbl 0955.01020. An extended version of (White 1997) with a list of Almgren's publications.
• Young, Laurence C. (1951), "Surfaces parametriques generalisees", Bulletin de la Société Mathématique de France, 79: 59–84, doi:10.24033/bsmf.1419, MR 0046421, Zbl 0044.10203.